CN115610422A - Steering guide torque control device for vehicle - Google Patents

Abstract

A steering guide torque control device for a vehicle. A control means for controlling a reaction force actuator for applying a steering guide torque to a steering wheel calculates a target steering angle for causing a vehicle to travel along a curve, calculates the target steering guide torque based on a deviation between the target steering angle and an actual steering angle, and controls the reaction force actuator so that the target steering guide torque is corrected so that the target steering guide torque becomes smaller as an index value of at least one of a number of times and an integrated time, which indicates that a difference between a magnitude of the actual steering angle and a magnitude of the target steering angle exceeds a reference value, becomes larger.

Description

Steering guide torque control device for vehicle

Technical Field

The present invention relates to a steering guide torque control device for a vehicle such as an automobile.

Background

As a steering reaction torque control device used for a vehicle such as an automobile, for example, a steering reaction torque control device configured to predict an appropriate (proper) steering operation amount of a driver based on a detection result of an external sensor and to make a steering reaction torque before the steering operation amount reaches the appropriate steering operation amount range larger than a conventional one when the driver's steering operation amount corresponding to a prediction timing of the appropriate steering operation amount is not within the appropriate steering operation amount range is known as described in japanese patent laid-open publication No. 2019-209844 described below.

The steering reaction torque acts as a steering reaction torque that resists the steering operation when the steering operation amount changes from within the appropriate steering operation amount range to outside the range, and acts as a steering torque that promotes the steering operation when the steering operation amount changes from outside the appropriate steering operation amount range to within the range. Accordingly, the steering reaction torque control device described in japanese patent application laid-open No. 2019-209844 described below may also be referred to as a steering guide torque control device.

As a steering guide torque control device, there is known a steering guide torque control device including: a target steering angle for causing the vehicle to travel along the curve is calculated based on the curvature of the curve of the travel path in front of the vehicle detected by a camera sensor, and a target steering guide torque is calculated based on a deviation between the target steering angle taking into account the read-ahead time and an actual steering angle, the target steering guide torque being a torque for guiding the steering of the driver so that the actual steering operation amount is within a range of a predetermined steering operation amount including the target steering operation amount, and the torque application device being controlled so that the steering guide torque becomes the target steering guide torque.

According to the steering reaction torque control device and the steering guide torque control device as described above, when the vehicle travels in a curve of the travel path, the driver can be prompted to perform the steering operation so that the actual steering angle becomes the target steering angle. Thus, the steering assist can be performed so that the steering operation amount of the driver becomes an appropriate steering operation amount while maintaining the feeling of the driver in steering.

Disclosure of Invention

In the steering guide torque control device, a target steering angle is calculated as a steering angle for causing the vehicle to travel along a curve based on a curvature of the curve of a traveling path in front of the vehicle. However, the driver may desire to perform curve running different from the curve running based on the target steering angle. For example, although the target steering angle may be calculated so that the vehicle travels along the center of the lane in a curve, the driver may want to travel in a curve in a mode such as outside-inside-outside (out-in-out) or a large curve.

When the driver desires to perform curve running different from the curve running based on the target steering angle, the driver performs the steering operation so that the actual steering angle is different from the target steering angle. Therefore, when the driver performs steering increase steering so that the actual steering angle deviates from the target steering angle, the driver inevitably feels discomfort in increasing the steering reaction force due to the steering guide torque.

The main object of the present invention is to provide a steering guide torque control device improved so as to reduce the possibility that the driver feels the discomfort of increasing the steering reaction force due to the steering guide torque when the vehicle is running on a curve.

According to the present invention, there is provided a steering guiding torque control device (10) for a vehicle, comprising: a steering input member (steering wheel 20) that is operated by a driver; a steering device (18) that steers the steered wheels (28 FL, 28 FR) in accordance with the amount of steering operation applied to the steering input member; a torque applying device (reaction force actuator 24) that applies a steering guide torque (Tsg) to the steering input member; a control unit (ECU 14) that controls the torque application device; and an imaging device (camera sensor 46) that acquires an image of the front of the vehicle, and the control unit is configured to perform steering guide torque control that is control in which: a curvature (rhopre) of a lane in front of a vehicle for driving the vehicle along the lane is estimated based on an image acquired by an imaging device, a target steering operation amount (theta t) is calculated based on the curvature of the lane, a target steering guide torque (Tsgt) is calculated based on a deviation (delta theta) between the target steering operation amount and an actual steering operation amount (theta), the target steering guide torque (Tsgt) is a torque for guiding the steering of the driver so that the actual steering operation amount is within a range of a predetermined steering operation amount including the target steering operation amount, and a torque applying device (reaction force actuator 24) is controlled so that the steering guide torque becomes the target steering guide torque.

The control unit (ECU 14) is configured to obtain an index value (Nin) indicating at least one of the number of times that the difference between the magnitude of the actual steering operation amount (theta) and the magnitude of the target steering operation amount (theta t) exceeds a reference value (theta a) and the integration time within the determination time (Tc) so far, and to correct the target steering guide torque (S10-S40) on the basis of the index value so that the magnitude of the target steering guide torque (Tsgt) decreases as the index value increases.

According to the above configuration, the target steering operation amount is calculated based on the curvature of the lane in front of the vehicle for running the vehicle along the lane, the target steering guide torque that guides the steering of the driver so that the actual steering operation amount is within the range of the predetermined steering operation amount including the target steering operation amount is calculated based on the deviation between the target steering operation amount and the actual steering operation amount, and the torque applying device is controlled so that the steering guide torque becomes the target steering guide torque. As a result, a steering guide torque for causing the vehicle to travel along the lane can be applied to the steering input member, and the driver can be prompted to perform a steering operation such that the actual steering operation amount becomes the target steering operation amount.

Further, according to the above configuration, an index value indicating at least one of the number of times and the integration time that the difference between the magnitude of the actual steering operation amount and the magnitude of the target steering operation amount exceeds the reference value in the determination time up to now is obtained. Further, the target steering guide torque is corrected based on the index value so that the larger the index value, the smaller the magnitude of the target steering guide torque. Thus, the possibility that the driver feels the discomfort of the increase in the steering reaction force due to the steering guide torque when the vehicle is running in a curve can be reduced as compared with the case where the target steering guide torque is not corrected based on the index value.

[ solution of the invention ]

In one aspect of the present invention, the control unit (ECU 14) is configured to decrease the ratio (S50 to S90) of the target steering guide torque (Tsgt) to the deviation (Δ θ) as the index value (Nin) increases.

According to the above aspect, the ratio of the target steering guide torque to the deviation is reduced as the index value is larger. Thus, the "the ratio of the target steering guide torque to the deviation can be reduced as the difference between the magnitude of the actual steering operation amount and the magnitude of the target steering operation amount exceeds the reference value and as the at least one of the number of times and the integrated time is increased within the determination time up to now". Therefore, the "the higher the tendency of the driver to perform curve running different from the curve running based on the target steering angle, the smaller the magnitude of the target steering guide torque" can be made.

In another aspect of the present invention, the control unit (ECU 14) is configured to increase and correct the magnitude of the target steering operation amount (θ t) by a correction amount (Δ θ a sign θ t) that increases as the index value (Nin) increases (S60, S100).

According to the above aspect, the magnitude of the target steering operation amount is corrected to be increased by the correction amount that becomes larger as the index value becomes larger. This makes it possible to reduce the magnitude of the target steering guide torque when the magnitude of the actual steering operation amount is larger than the magnitude of the target steering operation amount for which the increase correction is not performed.

Further, in another aspect of the present invention, the control unit (ECU 14) is configured to variably set the determination time (S40) according to the frequency of curve travel by the vehicle, such that the determination time (Tc) is longer as the frequency (frequency) of curve travel by the vehicle (60) is lower.

According to the above aspect, the determination time is set variably according to the frequency at which the vehicle travels in a curve, so that the determination time is longer as the frequency at which the vehicle travels in a curve is lower. Thus, the index value can be calculated as a value indicating a tendency of the driver to perform the steering operation so that the actual steering angle differs from the target steering angle, regardless of the magnitude of the number of curves on the traveling road.

Further, in another aspect of the present invention, the control unit (ECU 14) is configured to acquire information on the vehicle speed (V), and to variably set the reference value (θ a) according to the vehicle speed so that the reference value decreases as the vehicle speed increases (S60).

Generally, the larger the turning radius of a curve and the higher the vehicle speed, the smaller the steering angle when the vehicle travels around the curve. Further, the difference between the magnitude of the actual steering operation amount and the magnitude of the target steering operation amount is smaller as the vehicle speed is higher.

According to the above-described aspect, the reference value is variably set according to the vehicle speed such that the reference value decreases as the vehicle speed increases. Thus, the index value can be calculated as a value indicating a tendency of the driver to perform the steering operation so that the actual steering angle differs from the target steering angle, regardless of the magnitude of the turning radius of the curve.

Further, in another aspect of the present invention, the control unit (ECU 14) is configured to execute an automatic steering control that automatically steers the steering wheels (28 FL, 28 FR) by the steering device (18) so that the vehicle (60) travels along the lane even if the steering input member (steering wheel 20) is not steered by the driver, and is configured to suspend the automatic steering control and start the steering guide torque control (S20, S40 to S140) when it is determined that the steering operation of the steering input member by the driver is started during the execution period of the automatic steering control.

According to the above-described aspect, the automatic steering control is performed that is control to automatically steer the steering wheel by the steering device (18) so that the vehicle travels along the lane even if the steering input member is not steered by the driver. When it is determined that the steering operation of the steering input member by the driver is started during the execution of the automatic steering control, the automatic steering control is suspended and the steering guide torque control is started.

Accordingly, when the driver starts the steering operation of the steering input member during the execution of the automatic steering control, the automatic steering control can be automatically stopped, and the steering guide torque control can be automatically started without requiring a switch operation or the like.

In the above description, in order to facilitate understanding of the present invention, the names and/or reference numerals (reference numerals) used in the embodiment are given in parentheses for the components of the invention corresponding to the embodiment described later. However, the components of the present invention are not limited to the components of the embodiments corresponding to the names and/or reference numerals indicated in parentheses. Other objects, other features, and additional advantages of the present invention will be readily understood from the following description of the embodiments of the present invention with reference to the accompanying drawings.

Drawings

Features, advantages, and technical and industrial significance of exemplary embodiments of the present invention will be described below with reference to the accompanying drawings, in which like reference numerals represent like elements, and wherein:

fig. 1 is a schematic configuration diagram showing an embodiment of a vehicle steering guide torque control device configured as a steering reaction torque control device.

Fig. 2 is a diagram for explaining a shooting reference position and the like.

Fig. 3 is a flowchart showing a control routine of the steering reaction torque in the first embodiment.

Fig. 4 is a flowchart showing a calculation routine of the target basic steering guiding torque Tsgtb executed in step 70 of fig. 3.

Fig. 5 is a flowchart showing a control routine of the steering reaction torque in the second embodiment.

Fig. 6 is a flowchart showing a control routine of the steering reaction torque in the third embodiment.

Fig. 7 is a flowchart showing a routine of calculating the target steering guide torque Tsgt, which is executed in step 100 of fig. 6.

Fig. 8 is a flowchart showing a control routine of the steering reaction torque in the fourth embodiment.

Fig. 9 is a map for calculating the correction coefficient Ks based on the index value Nin.

Fig. 10 is a map for calculating the target basic steering guiding torque Tsgtb based on the deviation Δ θ of the steering angle.

Fig. 11 is a map for calculating the corrected steering angle Δ θ a based on the index value Nin.

Fig. 12 is a map for calculating the target steering guide torque Tsgt based on the deviation Δ θ of the steering angle.

Fig. 13 is a diagram showing a key of the correction of the target steering guide torque Tsgt in the first and second embodiments.

Fig. 14 is a diagram showing a key of the correction of the target steering guide torque Tsgt in the third and fourth embodiments.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the drawings.

[ first embodiment ]

< composition >

As shown in fig. 1, the steering guide torque control device 10 according to the first embodiment is configured as a steering reaction torque control device including a "steer-by-wire (electronic steer-by-wire) steering device 12" and an "electronic control unit 14 that controls the steering device 12", and the steering guide torque control device 10 is applied to a vehicle 60. In the first embodiment, as will be described later in detail, the steering guiding torque control device 10 also performs lane keeping control as automatic steering control, which is control for automatically steering a steering wheel so that the vehicle 60 travels along a lane.

In the following description and the drawings, the "electronic control unit" is denoted as "ECU". In addition, "LKA" is an abbreviation of Lane Keeping Assist, "Lane Keeping control" is denoted as LKA control.

Steering device 12 includes a steering input device 16 and a turning device 18 that are not mechanically connected to each other. The steering input device 16 includes a steering wheel 20, a steering angle detection device 22 that detects a rotation angle of the steering wheel as a steering angle θ, and a reaction force actuator 24 that applies a steering reaction torque Tre to the steering wheel.

The steering wheel 20 is a steering input member, not shown, which is operated by the driver, and may be in the form of a joystick. The reaction force actuator 24 includes an electric motor, and a rotating shaft 26 of the electric motor is integrally connected to the steering wheel 20. The steering angle detection device 22 may be a rotary encoder incorporated in the electric motor.

The steering device 18 includes: a steering mechanism 30 configured to receive steering torque Tst and steer left and right front wheels 28FL and 28FR as steered wheels; a steering actuator 32 that applies a steering torque to the steering mechanism; and a steering angle detection device 34 for detecting a steering angle δ of the steered wheel.

In the illustrated embodiment, the steering mechanism 30 includes a rack and pinion arrangement 40 having a rack 36 and a pinion shaft 38. Although not shown, the pinion shaft 38 has a pinion gear that meshes with the rack teeth of the rack 36, and the rotational motion of the pinion shaft 38 is converted into the reciprocating motion of the rack 36, and the reciprocating motion of the rack 36 is converted into the rotational motion of the pinion shaft 38. Further, the steering mechanism may have any configuration known in the art.

Further, the steering mechanism 30 includes tie rods (tie rod) 42L and 42R, and inner ends of the tie rods 42L and 42R are pivotally connected to left and right top ends of the rack 36, respectively. Although not shown, outer ends of the tie rods 42L and 42R are pivotally connected to knuckle arms (knuckle arm) of the front wheels 28FL and 28 FR. The steering actuator 32 includes an electric motor having a rotating shaft integrally coupled to a pinion shaft 38.

Thus, the steering mechanism 30 is configured to receive the steering torque from the steering actuator 32 via the pinion shaft 38 and steer the front wheels 28FL and 28 FR. Rotation angle of pinion shaft 38

(not shown) has a certain relationship with the rudder angle δ of the front wheels 28FL and 28 FR. Thus, in the illustrated embodiment, the steering angle detection device 34 detects the rotation angle of the rotation shaft of the electric motor of the pinion shaft 38 or the steering actuator 32

To detect the front wheelRudder angle δ of 28FL and 28 FR.

Not shown in detail in fig. 1, the ECU14 includes a microcomputer and a drive circuit. The microcomputer has a CPU, a ROM, a RAM, an interface (I/F), and the like, and has a general configuration in which they are connected to each other through a bidirectional common bus.

The ECU14 receives a signal indicating the steering angle θ detected by the steering angle detector 22, and receives a signal indicating the steering angle δ of the front wheels 28FL and 28FR detected by the steering angle detector 34. Further, a signal indicating the vehicle speed V detected by the vehicle speed sensor 44 and a signal indicating white line information of a lane in front of the vehicle 60 acquired by the camera sensor 46 are input to the ECU 14. The vehicle speed sensor 44 detects a vehicle speed V based on, for example, a wheel speed.

Further, a signal indicating whether or not the switch is on is input from the LKA switch 48 to the ECU 14. When the LKA switch 48 is turned on, the ECU14 executes LKA control.

As shown in fig. 3, the camera sensor 46 is fixed to an upper portion of the inner surface of the front windshield 50a of the vehicle 60, and captures an image of the front side of the vehicle 60 with a center of gravity 50b as a reference position of the vehicle 60 as a forward direction at a capturing reference position Pca having a distance Lca (positive constant). The distance Lca is referred to as a shooting reference distance Lca as necessary. The reference position of the vehicle 60 may be the positions of the front wheels 28FL and 28FR, the intermediate position between the front and rear wheels, or the like.

When the LKA switch 48 is off, the ECU14 sets the steering gear ratio (gear ratio) Rst to a standard steering gear ratio Rstn, and controls the steering actuator 32 based on the steering angle θ detected by the steering angle detection device 22. Thereby, the rudder angle δ of the front wheels 28FL and 28FR is controlled to θ/Rstn. The steering angle θ and the steering angle δ are 0 when the vehicle 60 is in the straight running state, and positive values when the vehicle 60 turns left. The standard steering gear ratio Rstn is a positive value that is set in advance so as to increase as the vehicle speed V increases, but may be a positive constant.

Further, the ECU14 calculates a basic steering reaction torque Treb to be applied to the steering wheel 20 based on the steering angle θ, the differential value of the steering angle θ, and the second-order differential value of the steering angle θ. The basic steering reaction torque Treb is variably set in accordance with the vehicle speed so that the basic steering reaction torque Treb becomes larger as the vehicle speed V becomes higher. The basic steering reaction torque Treb may be controlled by any means known in the art. For example, the basic steering reaction torque Treb may be a torque corresponding to a steering torque felt by the driver via the steering wheel in a vehicle in which the steering wheel is mechanically connected to the steered wheels and the steering assist torque is applied by the power steering device.

As will be described in detail later, the ECU14 calculates a target steering guide torque Tsgt that guides the steering of the driver when the vehicle 60 travels on a curve of the travel path. Further, the ECU14 controls the reaction force actuator 24 so that the steering reaction force torque Tre generated by the reaction force actuator 24 and applied to the steering wheel 20 becomes a target steering reaction force torque Tret that is the sum of the basic steering reaction force torque Treb and the target steering guide torque Tsgt. Thus, the reaction force actuator 24 functions as a torque applying device that applies the steering guide torque Tsg corresponding to the target steering guide torque Tsgt to the steering wheel 20. The magnitude of the target steering guide torque Tsgt is about one tenth of the magnitude of the basic steering reaction torque Treb.

When the driver performs steering increase steering so that the actual steering angle θ deviates from the target steering angle θ t, the target steering guide torque Tsgt acts in a direction to suppress the steering. On the other hand, when the driver performs the steering return steering so that the actual steering angle θ approaches the target steering angle θ t, the target steering guide torque Tsgt acts in a direction to promote the steering. Thus, the target steering guide torque Tsgt guides the steering of the driver so that the actual steering angle θ falls within a range of a predetermined steering operation amount including the target steering angle θ t.

In the embodiment, the ECU14 calculates the curve curvature ρ ca of the traveling road for the region centered on the imaging reference position Pca based on the white line information of the lane in front of the vehicle 60 acquired by the camera sensor 46, and stores the curve curvature ρ ca in the RAM. Thus, the camera sensor 46 and the ECU14 function as a detection device that detects the curve curvature ρ ca of the travel path for the region centered on the imaging reference position Pca.

Further, the ECU14 reads out the curve curvature ρ ca corresponding to the read-ahead time Δ t from the RAM as the read-ahead curve curvature ρ pre, calculates a target steering angle θ t based on the curve curvature ρ pre, and calculates a steering guide torque Tsg based on a deviation Δ θ between the target steering angle θ t and the actual steering angle θ. The target steering angle θ t is a target steering angle for making it easy for the actual steering angle to stay within an appropriate range so that the vehicle 60 travels along a curve. In the embodiment, the curvature of the vehicle 60 in the left turn direction is positive.

Curvature of curve rho ca [1/m ]]The calculation is performed according to the following equation (1). In the following formula (1), V is a vehicle speed [ m/s ]]，ρ ₀ Is the curve curvature [1/m ] of the running path at the center of gravity 50b of the vehicle 60]. Thus, ρ ₀ The curve curvature ρ ca is calculated and stored in the RAM before the time Lca/V required for the vehicle 60 to travel the imaging reference distance Lca shown in fig. 1.Δ ρ is the rate of change [1/m ] of the curve curvature ρ ca calculated before the time Lca/V and stored in the RAM]I.e. the amount of change per unit distance of curvature of the curve.

ρca＝ρ ₀ +VΔtΔρ…(1)

As shown in fig. 1, a distance (pre-reading distance) Lpre between the center of gravity 50b of the vehicle 60 and the pre-reading position Ppre is smaller than the shooting reference distance Lca. Further, the pre-read distance Lpre may not be constant. As is apparent from the above description, the curve curvature ρ pre is the curve curvature at the pre-reading position Ppre, that is, the curve curvature at the position where the center of gravity 50b of the vehicle 60 arrives after the pre-reading time Δ t.

Target steering angle θ t [ deg ]]The calculation is performed according to the following equation (2). In the following equation (2), rst is a steering gear ratio, and a is a stability factor of the vehicle 60 [ deg/(m), as described above ² /s ² )]And Lw is the wheelbase of the vehicle 60. The stability factor a and the wheel base Lw are known constant values determined by the specifications of the vehicle 60.

θt＝Rst(1+AV ² )ρpreLw···(2)

The ECU14 calculates a deviation Δ θ of the steering angle, which is a deviation θ - θ t of the actual steering angle θ from the target steering angle θ t, and calculates the target basic steering guide torque Tsgtb based on the deviation Δ θ of the steering angle by referring to the map shown in fig. 10.

In particular, the ECU14 calculates the number of times that the difference between the absolute value of the actual steering angle θ and the absolute value of the target steering angle θ t exceeds the reference value θ a within the determination time Tc up to now as the index value Nin. The ECU14 calculates the correction coefficient Ks by referring to the map shown in fig. 9 based on the index value Nin.

Note that the determination time Tc may be constant, but in this embodiment and other embodiments described later, the determination time Tc is set variably in accordance with the frequency at which the vehicle performs curve traveling so that the determination time Tc becomes longer as the frequency at which the vehicle 60 performs curve traveling becomes lower. In this embodiment and other embodiments described later, the reference value θ a may be set variably in accordance with the vehicle speed so that the reference value θ a decreases as the vehicle speed V increases.

Further, the ECU14 calculates the target steering guide torque Tsgt as a product KsTsgtb of the correction coefficient Ks and the target basic steering guide torque Tsgtb. Further, the ECU14 controls the reaction force actuator 24 so that the steering reaction force torque Tre becomes the target steering reaction force torque Tret.

When the LKA switch 48 is on and the driver does not perform the steering operation, the ECU14 does not perform the steering guide torque control and performs the LKA control. Further, when the LKA switch 48 is turned on and LKA control is being executed, the ECU14 stops LKA control and executes steering guide torque control when a steering operation is performed by the driver.

< control routine of steering reaction torque >

Next, a control routine of the steering reaction torque according to the first embodiment will be described. The CPU of the ECU14 executes a control routine of the steering reaction torque shown in the flowchart of fig. 3 every time a predetermined time elapses when an ignition switch, not shown, is turned on. Further, a control program corresponding to the flowchart of fig. 3 is stored in the ROM of the ECU 14.

First, in step S10, the CPU determines whether or not the LKA switch 48 is on. If no, the CPU proceeds to step S40, and if yes, proceeds to step S20.

In step S20, the CPU determines whether or not a steering operation involving LKA control is performed by the driver. If no, the CPU executes LKA control in step S30, and if yes, advances the control of the steering reaction torque to step S40. Note that LKA control may be performed in any manner known in the art, and whether or not a steering operation involving LKA control is performed by the driver may be determined in any manner known in the art.

In step S40, the CPU determines the determination time Tc based on the frequency of curve traveling of the vehicle 60 as described above, and determines the reference value θ a based on the vehicle speed V as described above. Further, the CPU calculates the number of times that the difference between the absolute value of the actual steering angle θ and the absolute value of the target steering angle θ t exceeds the reference value θ a within the determination time Tc up to now as the index value Nin.

In step S50, the CPU calculates the correction coefficient Ks by referring to the map shown in fig. 9 based on the index value Nin. As shown in fig. 9, the correction coefficient Ks is 1 when the index value Nin is 0, and is smaller when the index value Nin is smaller than Nins (positive constant), and is calculated to be a constant value of Ksmin when the index value Nin is equal to or greater than Nins.

In step S70, the CPU calculates the target basic steering guide torque Tsgtb according to the flowchart shown in fig. 4.

In step S90, the CPU calculates a target steering guide torque Tsgt, which is a torque for guiding the steering of the driver when the vehicle 60 travels on the curve of the traveling path, as a product kststsgtb of the correction coefficient Ks and the target basic steering guide torque Tsgtb.

In step S120, the CPU calculates a basic steering reaction torque Treb to be applied to the steering wheel 20 based on the steering angle θ, the differential value of the steering angle θ, the second order differential value of the steering angle θ, and the vehicle speed V, in accordance with any of the techniques known in the art.

In step S130, the CPU calculates the target steering reaction torque Tret as the sum Treb + Tsgt of the basic steering reaction torque Treb and the target steering guide torque Tsgt.

In step S140, the CPU controls the reaction force actuator 24 so that the steering reaction force torque Tre generated by the reaction force actuator 24 becomes the target steering reaction force torque Tret. Thus, by applying the steering reaction torque corresponding to the target steering reaction torque Tret to the steering wheel 20, the steering guide torque Tsg corresponding to the target steering guide torque Tsgt can be applied to the steering wheel 20.

In step S72 of the flowchart shown in fig. 4, the CPU calculates a curve curvature change rate Δ ρ for a region centered on the imaging reference position Pca based on white line information of the lane in front of the vehicle 60 acquired by the camera sensor 46, and stores the curve curvature change rate Δ ρ in the RAM.

In step S74, the curve curvature ρ ca of the traveling road is calculated for the region centered on the imaging reference position Pca based on the above expression (1) and stored in the RAM. Further, the curve curvature ρ ca may be set to 0 during the period from the start of the control to the elapsed time Lca/V.

In step S76, the CPU reads out, from the RAM, the curve curvature ρ ca that was calculated before the pre-read time Δ t and that was stored in the RAM, as the curve curvature ρ pre at the pre-read position Ppre.

In step S78, the CPU calculates a target steering angle θ t as a target steering operation amount for causing the vehicle 60 to travel along the curve of the travel path based on the vehicle speed V and the curve curvature ρ pre at the pre-read position Ppre, based on the above expression (2).

In step S80, the CPU calculates a deviation θ - θ t between the actual steering angle θ detected by the steering angle detection device 22 and the target steering angle θ t, that is, a deviation Δ θ of the steering angle.

In step S82, the CPU calculates the target basic steering guide torque Tsgtb based on the deviation Δ θ of the steering angle with reference to the map shown in fig. 10. As shown in fig. 10, when the absolute value of the deviation Δ θ of the steering angle is smaller than Δ θ c (a positive constant), the magnitude of the target basic steering guide torque Tsgtb becomes larger as the absolute value of the deviation Δ θ of the steering angle becomes larger, and when the absolute value of the deviation Δ θ of the steering angle becomes equal to or larger than Δ θ c, the magnitude of the target basic steering guide torque Tsgtb is calculated to be a constant value Tsgtbmax.

[ second embodiment ]

Fig. 5 is a flowchart showing a control routine of the steering reaction torque in the second embodiment configured as a modification of the first embodiment. In fig. 5, steps that are the same as the steps shown in fig. 3 are given the same step numbers as the steps shown in fig. 3. This also applies to other embodiments described later.

In the second embodiment and a fourth embodiment described later, LKA control is not executed. Thus, although not shown, the LKA switch 48 is not provided in the steering guiding torque control device 10 according to these embodiments.

As is clear from comparison between fig. 5 and fig. 3, steps 40 to 140 are performed in the same manner as steps 40 to 140 of the first embodiment, respectively, without performing steps 10 to 30 of the first embodiment.

According to the first and second embodiments, the number of times that the difference between the absolute value of the actual steering angle θ and the absolute value of the target steering angle θ t exceeds the reference value θ a within the determination time Tc up to now is calculated as the index value Nin (step S40). The correction coefficient Ks is calculated based on the index value Nin (step S50), and the target basic steering guide torque Tsgtb is calculated (step S70). Further, the target steering guide torque Tsgt is calculated as a product KsTsgtb of the correction coefficient Ks and the target basic steering guide torque Tsgtb (step S90).

The correction coefficient Ks is calculated such that the larger the index value Nin is, the smaller the correction coefficient Ks is (fig. 9), and therefore the larger the index value Nin is, the lower the ratio of the target steering guide torque Tsgt to the deviation Δ θ is. Therefore, the higher the tendency of the driver to perform curve running different from the curve running based on the target steering angle, the smaller the magnitude of the target steering guide torque can be made.

Fig. 13 shows the relationship between the absolute value of the actual steering angle θ and the absolute value of the index value Nin and the target steering guide torque Tsgt. As shown in fig. 13, the larger the index value Nin is, the smaller the magnitude of the target steering guide torque Tsgt in the region where the magnitude of the actual steering angle θ exceeds the magnitude of the target steering angle θ t is. As can be seen from fig. 13, it is possible to make: when the steering operation is performed so that the magnitude of the actual steering angle θ is larger than the magnitude of the target steering angle θ t, the reaction torque generated by the steering guide torque is reduced as the index value Nin is larger.

[ third embodiment ]

Fig. 6 is a flowchart showing a control routine of the steering reaction torque in the third embodiment of the present invention.

As is clear from comparison between fig. 6 and fig. 3, in the second embodiment, steps 10 to 40 and steps 120 to 140 are performed in the same manner as in the first embodiment. When step 40 is complete, steps 60 and 100 are performed.

In step S60, the CPU calculates the corrected steering angle Δ θ a based on the index value Nin with reference to the map shown in fig. 11. As shown in fig. 11, the corrected steering angle Δ θ a is 0 when the index value Nin is 0, the corrected steering angle Δ θ a is larger when the index value Nin is smaller than Nina (a positive constant), and the corrected steering angle Δ θ a is calculated to be a constant value Δ θ amax when the index value Nin is equal to or larger than Nina.

In step S100, the CPU calculates a target steering guide torque Tsgt according to the flowchart shown in fig. 7.

As is apparent from comparison between fig. 7 and fig. 4, steps 102 to 108 are performed in the same manner as steps 72 to 78 of the first embodiment, respectively.

In step S110 executed subsequent to step S108, sign θ t is set to the sign (sign) of the target steering angle θ t, and the deviation Δ θ of the steering angle is calculated according to the following expression (3). That is, the deviation Δ θ of the steering angle is calculated as a deviation θ - (θ t + Δ θ a · sign θ t) between the actual steering angle θ detected by the steering angle detecting device 22 and the target steering angle θ ta (= θ t + Δ θ a · sign θ t) corrected to increase in magnitude by the corrected steering angle Δ θ a).

Δθ＝θ-(θt+Δθa·signθt)

＝θ-θt-Δθa·signθt···(3)

In step S112, the CPU calculates a target steering guide torque Tsgt based on the deviation Δ θ of the steering angle by referring to the map shown in fig. 12. As shown in fig. 12, the target steering guide torque Tsgt increases as the absolute value of the deviation Δ θ of the steering angle increases when the absolute value of the deviation Δ θ of the steering angle is smaller than Δ θ c, and the target steering guide torque Tsgt is calculated to be a constant value Tsgtmax when the absolute value of the deviation Δ θ of the steering angle is equal to or larger than Δ θ c.

[ fourth embodiment ]

Fig. 8 is a flowchart showing a control routine of the steering reaction torque in the fourth embodiment configured as a modification of the third embodiment.

As is clear from comparison between fig. 8 and fig. 6, steps 10 to 30 in the third embodiment are not executed, and steps 40 to 140 are executed in the same manner as steps 40 to 140 in the third embodiment, respectively.

According to the third and fourth embodiments, the number of times the difference between the absolute value of the actual steering angle θ and the absolute value of the target steering angle θ t exceeds the reference value θ a within the determination time Tc up to now is calculated as the index value Nin (step S40). The corrected steering angle Δ θ a is calculated based on the index value Nin (step S60), and the target steering guide torque Tsgt is calculated according to the flowchart shown in fig. 7 (step S100).

The deviation Δ θ of the steering angle is calculated as a deviation between the actual steering angle θ and the target steering angle θ t + Δ θ a sign θ t corrected to be increased in magnitude by the corrected steering angle Δ θ a (step S110). This makes it possible to reduce the magnitude of the target steering guide torque Tsgt when the magnitude of the actual steering angle θ is larger than the magnitude of the target steering angle that is not subjected to the increase correction.

In addition, according to the first and third embodiments described above, when the driver performs a steering operation to be involved in LKA control while the LKA switch 48 is on, steps S10 and S20 determine yes, and steps S40 to S140 are executed. Accordingly, when the driver starts an intervention steering operation during execution of the LKA control, the LKA control can be automatically stopped, and the steering guide torque control can be automatically started without requiring a switch operation or the like.

< common Effect of the first to fourth embodiments >

As is apparent from the above description, according to the first to fourth embodiments, the target steering guide torque can be corrected based on the index value Nin such that the magnitude of the target steering guide torque Tsgt is reduced as the index value Nin is increased. Thus, compared to the case where the target steering guide torque is not corrected based on the index value, the possibility that the driver feels the discomfort of the increase in the steering reaction force due to the steering guide torque when the vehicle is running in a curve can be reduced.

Further, according to the first to fourth embodiments described above, the determination time Tc is variably set according to the frequency at which the vehicle performs curve traveling so that the determination time Tc becomes longer as the frequency at which the vehicle 60 performs curve traveling becomes lower. Thus, the index value can be calculated as a value representing the tendency of the driver to perform the steering operation so that the actual steering angle differs from the target steering angle, regardless of the magnitude of the number of turns.

Further, according to the first to fourth embodiments described above, the reference value θ a is variably set according to the vehicle speed so that the reference value θ a becomes smaller as the vehicle speed V becomes higher. Thus, the index value can be calculated as a value indicating a tendency of the driver to perform the steering operation so that the actual steering angle differs from the target steering angle, regardless of the magnitude of the turning radius of the curve.

While the present invention has been described in detail with reference to the specific embodiments, it is apparent to those skilled in the art that the present invention is not limited to the embodiments described above, and various other embodiments can be implemented within the scope of the present invention.

For example, in the above-described embodiment, the index value Nin is calculated as the number of times that the difference between the absolute value of the actual steering angle θ and the absolute value of the target steering angle θ t exceeds the reference value θ a within the determination time Tc up to now. However, the index value Nin may be calculated as an integrated time in which the difference between the absolute value of the actual steering angle θ and the absolute value of the target steering angle θ t exceeds the reference value θ a within the determination time Tc up to now. Further, nc and Tc may be the number of times and the integration time, respectively, and α and β may be positive constants, and the index value Nin may be calculated as a linear sum α Nc + β Tc of the number of times and the integration time based on both the number of times and the integration time.

In the above-described embodiment, the automatic steering control is LKA control in which the steering wheels (28 FL, 28 FR) are automatically steered by the steering device (18) so that the vehicle (60) travels along the lane even if the steering input member (steering wheel 20) is not steered by the driver. However, the automatic steering control may be any automatic steering control known in the art, and may be, for example, an automatic driving control.

In the first and third embodiments described above, when the driver performs the steering operation involving the LKA control, the LKA control is suspended, and the steering guide torque control in steps S40 to S140 is automatically started. However, the steering guide torque control that is started when the driver performs the steering operation involving the LKA control may be the steering guide torque control in which the target steering guide torque is not corrected based on the index value.

Further, in the above-described embodiment, the steering guide torque control device 10 is configured as a steering reaction torque control device including the steer-by-wire type steering device 12. However, the steering guide torque control device 10 may be a steering reaction torque control device including an electric power steering device in which a steering wheel is mechanically connected to left and right front wheels. In this case, the target steering assist torque Tsat is calculated as the sum of the basic steering assist torque Tsab calculated based on the steering torque and the vehicle speed and the target steering guide torque Tsgt. Further, the electric power steering device is controlled so that the steering assist torque Tsa generated by the electric power steering device becomes the target steering assist torque Tsa.

Claims (6)

1. A steering guide torque control device for a vehicle,

the method comprises the following steps: a steering input means for performing a steering operation by a driver; a steering device that steers a steering wheel in accordance with a steering operation amount applied to the steering input member; a torque applying device that applies a steering guide torque to the steering input member; a control unit that controls the torque application device; and a camera for capturing an image of the front of the vehicle,

the control unit is configured to perform steering guide torque control that is control in which: estimating a curvature of a lane ahead of the vehicle for running the vehicle along the lane based on the image acquired by the imaging device, calculating a target steering operation amount based on the curvature of the lane, calculating a target steering guide torque based on a deviation between the target steering operation amount and an actual steering operation amount, the target steering guide torque being a torque for guiding steering of the driver such that the actual steering operation amount is within a range of a predetermined steering operation amount including the target steering operation amount, and controlling the torque applying device such that the steering guide torque becomes the target steering guide torque,

the control means is configured to obtain an index value indicating at least one of the number of times a difference between a magnitude of an actual steering operation amount and a magnitude of the target steering operation amount exceeds a reference value and an integration time within a determination time up to now, and to correct the target steering guide torque based on the index value such that the larger the index value is, the smaller the magnitude of the target steering guide torque is.

2. The vehicular steering guiding torque control device according to claim 1,

the control unit is configured to decrease the ratio of the target steering guide torque to the deviation as the index value increases.

3. The vehicular steering guiding torque control apparatus according to claim 2,

the control means is configured to increase and correct the magnitude of the target steering operation amount by a correction amount that increases as the index value increases.

4. The vehicular steering guiding torque control apparatus according to any one of claims 1 to 3,

the control unit is configured to set the determination time to be variable according to the frequency at which the vehicle travels in a curve, so that the determination time is longer as the frequency at which the vehicle travels in a curve is lower.

5. The vehicular steering guiding torque control device according to claim 4,

the control means is configured to acquire information on a vehicle speed, and to variably set the reference value according to the vehicle speed such that the reference value decreases as the vehicle speed increases.

6. The vehicular steering guiding torque control apparatus according to any one of claims 1 to 5,

the control unit is configured to execute an automatic steering control that is a control for automatically steering the steering wheel by the steering device so that the vehicle travels along the lane even if the steering input member is not operated by the driver, and configured to suspend the automatic steering control and start the steering guide torque control when it is determined that the driver starts the steering operation of the steering input member during execution of the automatic steering control.

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